#!/usr/bin/env python2 # -*- coding: UTF-8 no BOM -*- import os,sys,math,re,time,struct import damask from optparse import OptionParser, OptionGroup scriptName = os.path.splitext(os.path.basename(__file__))[0] scriptID = ' '.join([scriptName,damask.version]) fileExtensions = { \ 'marc': ['.t16',], 'spectral': ['.spectralOut',], } # ----------------------------- class vector: # mimic py_post node object x,y,z = [None,None,None] def __init__(self,coords): self.x = coords[0] self.y = coords[1] self.z = coords[2] # ----------------------------- class element: # mimic py_post element object items = [] type = None def __init__(self,nodes,type): self.items = nodes self.type = type # ----------------------------- class elemental_scalar: # mimic py_post element_scalar object id = None value = None def __init__(self,node,value): self.id = node self.value = value # ----------------------------- class MPIEspectral_result: # mimic py_post result object file = None dataOffset = 0 N_elemental_scalars = 0 grid = [0,0,0] size = [0.0,0.0,0.0] theTitle = '' wd = '' geometry = '' extrapolate = '' N_loadcases = 0 N_increments = 0 N_positions = 0 _frequencies = [] _increments = [] _times = [] increment = 0 startingIncrement = 0 position = 0 # this is a dummy at the moment, we need to parse the load file and figure out what time a particular increment corresponds to time = 0.0 N_nodes = 0 N_node_scalars = 0 N_elements = 0 N_element_scalars = 0 N_element_tensors = 0 def __init__(self,filename): self.file = open(filename, 'rb') self.filesize = os.path.getsize(filename) self.dataOffset = 0 while self.dataOffset < self.filesize: self.file.seek(self.dataOffset) if self.file.read(3) == 'eoh': break self.dataOffset += 1 self.dataOffset += 7 #search first for the new keywords with ':', if not found try to find the old ones self.theTitle = self._keyedString('load:') if self.theTitle is None: self.theTitle = self._keyedString('load') self.wd = self._keyedString('workingdir:') if self.wd is None: self.wd = self._keyedString('workingdir') self.geometry = self._keyedString('geometry:') if self.geometry is None: self.geometry = self._keyedString('geometry') self.N_loadcases = self._keyedPackedArray('loadcases:',count=1,type='i')[0] if self.N_loadcases is None: self.N_loadcases = self._keyedPackedArray('loadcases',count=1,type='i')[0] self._frequencies = self._keyedPackedArray('frequencies:',count=self.N_loadcases,type='i') if all ( i is None for i in self._frequencies): self._frequencies = self._keyedPackedArray('frequencies',count=self.N_loadcases,type='i') self._increments = self._keyedPackedArray('increments:',count=self.N_loadcases,type='i') if all (i is None for i in self._increments): self._increments = self._keyedPackedArray('increments',count=self.N_loadcases,type='i') self.startingIncrement = self._keyedPackedArray('startingIncrement:',count=1,type='i')[0] if self.startingIncrement is None: self.startingIncrement = self._keyedPackedArray('startingIncrement',count=1,type='i')[0] self._times = self._keyedPackedArray('times:',count=self.N_loadcases,type='d') if all (i is None for i in self._times): self._times = self._keyedPackedArray('times',count=self.N_loadcases,type='d') self._logscales = self._keyedPackedArray('logscales:',count=self.N_loadcases,type='i') if all (i is None for i in self._logscales): self._logscales = self._keyedPackedArray('logscales',count=self.N_loadcases,type='i') self.size = self._keyedPackedArray('size:',count=3,type='d') if self.size == [None,None,None]: # no 'size' found, try legacy alias 'dimension' self.size = self._keyedPackedArray('dimension',count=3,type='d') self.grid = self._keyedPackedArray('grid:',count=3,type='i') if self.grid == [None,None,None]: # no 'grid' found, try legacy alias 'resolution' self.grid = self._keyedPackedArray('resolution',count=3,type='i') self.N_nodes = (self.grid[0]+1)*(self.grid[1]+1)*(self.grid[2]+1) self.N_elements = self.grid[0] * self.grid[1] * self.grid[2] self.N_element_scalars = self._keyedPackedArray('materialpoint_sizeResults:',count=1,type='i')[0] if self.N_element_scalars is None: self.N_element_scalars = self._keyedPackedArray('materialpoint_sizeResults',count=1,type='i')[0] self.N_positions = (self.filesize-self.dataOffset)/(self.N_elements*self.N_element_scalars*8) self.N_increments = 1 # add zero'th entry for i in range(self.N_loadcases): self.N_increments += self._increments[i]//self._frequencies[i] # parameters for file handling depending on output format if options.legacy: self.tagLen=8 self.fourByteLimit = 2**31 -1 -8 else: self.tagLen=0 self.expectedFileSize = self.dataOffset+self.N_increments*(self.tagLen+self.N_elements*self.N_element_scalars*8) if options.legacy: self.expectedFileSize+=self.expectedFileSize//self.fourByteLimit*8 # add extra 8 bytes for additional headers at 4 GB limits if self.expectedFileSize != self.filesize: print '\n**\n* Unexpected file size. Incomplete simulation or file corrupted!\n**' def __str__(self): """Summary of results file""" return '\n'.join([ 'workdir: %s'%self.wd, 'geometry: %s'%self.geometry, 'loadcases: %i'%self.N_loadcases, 'grid: %s'%(','.join(map(str,self.grid))), 'size: %s'%(','.join(map(str,self.size))), 'header size: %i'%self.dataOffset, 'actual file size: %i'%self.filesize, 'expected file size: %i'%self.expectedFileSize, 'positions in file : %i'%self.N_positions, 'starting increment: %i'%self.startingIncrement, ] ) def locateKeyValue(self,identifier): key = {'name':None,'pos':None} name = '' filepos=0 # start at the beginning while name != identifier and filepos < self.dataOffset: # stop searching when found or when reached end of header self.file.seek(filepos) # read the starting tag in front of the keyword (Fortran indicates start and end of writing by a 4 byte tag indicating the length of the following data) dataLen=struct.unpack('i',self.file.read(4))[0] name = self.file.read(len(identifier)) # anticipate identifier start=filepos+(4+len(identifier)) # position of the values for the found key filepos=filepos+(4+dataLen+4) # forward to next keyword if name==identifier: # found the correct name key['pos'] = start # save position key['name'] = name return key def _keyedPackedArray(self,identifier,count = 3,type = 'd',default = None): bytecount = {'d': 8,'i': 4} values = [default]*count key = self.locateKeyValue(identifier) if key['name'] == identifier and key['pos'] is not None: self.file.seek(key['pos']) for i in range(count): values[i] = struct.unpack(type,self.file.read(bytecount[type]))[0] return values def _keyedString(self,identifier,default=None): value = default self.file.seek(0) m = re.search(r'(.{4})%s(.*?)\1'%identifier,self.file.read(self.dataOffset),re.DOTALL) if m: value = m.group(2) return value def title(self): return self.theTitle def moveto(self,pos): self.position = pos self.increment = 0 self.time = 0.0 p = pos for l in range(self.N_loadcases): if p <= self._increments[l]//self._frequencies[l]: break else: self.increment += self._increments[l] self.time += self._times[l] p -= self._increments[l]//self._frequencies[l] self.increment += self._frequencies[l] * p if self._logscales[l] > 0: # logarithmic time scale if l == 0: self.time = 2**(self._increments[l] - (1+self._frequencies[l]*p)) * self._times[l] # first loadcase else: self.time *= ((self.time + self._times[l])/self.time)**((1+self._frequencies[l]*p)/self._increments[l]) # any subsequent loadcase else: # linear time scale self.time += self._times[l]/self._increments[l] * self._frequencies[l] * p def extrapolation(self,value): self.extrapolate = value def node_sequence(self,n): return n-1 def node_id(self,n): return n+1 def node(self,n): a = self.grid[0]+1 b = self.grid[1]+1 c = self.grid[2]+1 return vector([self.size[0] * (n%a) / self.grid[0], self.size[1] * ((n/a)%b) / self.grid[1], self.size[2] * ((n/a/b)%c) / self.grid[2], ]) def element_sequence(self,e): return e-1 def element_id(self,e): return e+1 def element(self,e): a = self.grid[0]+1 b = self.grid[1]+1 basenode = 1 + e+e/self.grid[0] + e/self.grid[0]/self.grid[1]*a basenode2 = basenode+a*b return (element([basenode ,basenode +1,basenode +a+1,basenode +a, basenode2 ,basenode2+1,basenode2+a+1,basenode2+a, ],117)) def increments(self): return self.N_positions def nodes(self): return self.N_nodes def node_scalars(self): return self.N_node_scalars def elements(self): return self.N_elements def element_scalars(self): return self.N_element_scalars def element_scalar(self,e,idx): if not options.legacy: incStart = self.dataOffset \ + self.position*8*self.N_elements*self.N_element_scalars where = (e*self.N_element_scalars + idx)*8 try: self.file.seek(incStart+where) value = struct.unpack('d',self.file.read(8))[0] except: print 'seeking',incStart+where print 'e',e,'idx',idx sys.exit(1) else: self.fourByteLimit = 2**31 -1 -8 # header & footer + extra header and footer for 4 byte int range (Fortran) # values incStart = self.dataOffset \ + self.position*8*( 1 + self.N_elements*self.N_element_scalars*8//self.fourByteLimit \ + self.N_elements*self.N_element_scalars) where = (e*self.N_element_scalars + idx)*8 try: if where%self.fourByteLimit + 8 >= self.fourByteLimit: # danger of reading into fortran record footer at 4 byte limit data='' for i in xrange(8): self.file.seek(incStart+where+(where//self.fourByteLimit)*8+4) data += self.file.read(1) where += 1 value = struct.unpack('d',data)[0] else: self.file.seek(incStart+where+(where//self.fourByteLimit)*8+4) value = struct.unpack('d',self.file.read(8))[0] except: print 'seeking',incStart+where+(where//self.fourByteLimit)*8+4 print 'e',e,'idx',idx sys.exit(1) return [elemental_scalar(node,value) for node in self.element(e).items] def element_scalar_label(elem,idx): return 'User Defined Variable %i'%(idx+1) def element_tensors(self): return self.N_element_tensors # ----------------------------- def ipCoords(elemType, nodalCoordinates): """returns IP coordinates for a given element""" nodeWeightsPerNode = { 7: [ [27.0, 9.0, 3.0, 9.0, 9.0, 3.0, 1.0, 3.0], [ 9.0, 27.0, 9.0, 3.0, 3.0, 9.0, 3.0, 1.0], [ 3.0, 9.0, 27.0, 9.0, 1.0, 3.0, 9.0, 3.0], [ 9.0, 3.0, 9.0, 27.0, 3.0, 1.0, 3.0, 9.0], [ 9.0, 3.0, 1.0, 3.0, 27.0, 9.0, 3.0, 9.0], [ 3.0, 9.0, 3.0, 1.0, 9.0, 27.0, 9.0, 3.0], [ 1.0, 3.0, 9.0, 3.0, 3.0, 9.0, 27.0, 9.0], [ 3.0, 1.0, 3.0, 9.0, 9.0, 3.0, 9.0, 27.0] ], 57: [ [27.0, 9.0, 3.0, 9.0, 9.0, 3.0, 1.0, 3.0], [ 9.0, 27.0, 9.0, 3.0, 3.0, 9.0, 3.0, 1.0], [ 3.0, 9.0, 27.0, 9.0, 1.0, 3.0, 9.0, 3.0], [ 9.0, 3.0, 9.0, 27.0, 3.0, 1.0, 3.0, 9.0], [ 9.0, 3.0, 1.0, 3.0, 27.0, 9.0, 3.0, 9.0], [ 3.0, 9.0, 3.0, 1.0, 9.0, 27.0, 9.0, 3.0], [ 1.0, 3.0, 9.0, 3.0, 3.0, 9.0, 27.0, 9.0], [ 3.0, 1.0, 3.0, 9.0, 9.0, 3.0, 9.0, 27.0] ], 117: [ [ 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0] ], 125: [ [ 3.0, 0.0, 0.0, 4.0, 1.0, 4.0], [ 0.0, 3.0, 0.0, 4.0, 4.0, 1.0], [ 0.0, 0.0, 3.0, 1.0, 4.0, 4.0],], 127: [ [ 45.0, 17.0, 17.0, 17.0], [ 17.0, 45.0, 17.0, 17.0], [ 17.0, 17.0, 45.0, 17.0], [ 17.0, 17.0, 17.0, 45.0],], 136: [ [42.0, 15.0, 15.0, 14.0, 5.0, 5.0], [15.0, 42.0, 15.0, 5.0, 14.0, 5.0], [15.0, 15.0, 42.0, 5.0, 5.0, 14.0], [14.0, 5.0, 5.0, 42.0, 15.0, 15.0], [ 5.0, 14.0, 5.0, 15.0, 42.0, 15.0], [ 5.0, 5.0, 14.0, 15.0, 15.0, 42.0] ], } Nips = len(nodeWeightsPerNode[elemType]) ipCoordinates = [[0.0,0.0,0.0] for i in range(Nips)] for ip in range(Nips): for node in range(len(nodeWeightsPerNode[elemType][ip])): for i in range(3): ipCoordinates[ip][i] += nodeWeightsPerNode[elemType][ip][node] * nodalCoordinates[node][i] for i in range(3): ipCoordinates[ip][i] /= sum(nodeWeightsPerNode[elemType][ip]) return ipCoordinates # ----------------------------- def ipIDs(elemType): """returns IP numbers for given element type""" ipPerNode = { 7: [ 1, 2, 4, 3, 5, 6, 8, 7 ], 57: [ 1, 2, 4, 3, 5, 6, 8, 7 ], 117: [ 1 ], 125: [ 1, 2, 3 ], 127: [ 1, 2, 3, 4 ], 136: [ 1, 2, 3, 4, 5, 6 ], } return ipPerNode[elemType] # ----------------------------- def substituteLocation(string, mesh, coords): """do variable interpolation in group and filter strings""" substitute = string substitute = substitute.replace('elem', str(mesh[0])) substitute = substitute.replace('node', str(mesh[1])) substitute = substitute.replace('ip', str(mesh[2])) substitute = substitute.replace('grain', str(mesh[3])) substitute = substitute.replace('x', '%.6g'%coords[0]) substitute = substitute.replace('y', '%.6g'%coords[1]) substitute = substitute.replace('z', '%.6g'%coords[2]) return substitute # ----------------------------- def heading(glue,parts): """joins pieces from parts by glue. second to last entry in pieces tells multiplicity""" header = [] for pieces in parts: if pieces[-2] == 0: del pieces[-2] header.append(glue.join(map(str,pieces))) return header # ----------------------------- def mapIncremental(label, mapping, N, base, new): """ applies the function defined by "mapping" (can be either 'min','max','avg', 'sum', or user specified) to a list of data """ theMap = { 'min': lambda n,b,a: a if n==0 else min(b,a), 'max': lambda n,b,a: a if n==0 else max(b,a), 'avg': lambda n,b,a: (n*b+a)/(n+1), 'avgabs': lambda n,b,a: (n*b+abs(a))/(n+1), 'sum': lambda n,b,a: a if n==0 else b+a, 'sumabs': lambda n,b,a: abs(a) if n==0 else b+abs(a), 'unique': lambda n,b,a: a if n==0 or b==a else 'n/a' } if mapping in theMap: mapped = map(theMap[mapping],[N]*len(base),base,new) # map one of the standard functions to data if label.lower() == 'orientation': # orientation is special case:... orientationNorm = math.sqrt(sum([q*q for q in mapped])) # ...calc norm of average quaternion mapped = map(lambda x: x/orientationNorm, mapped) # ...renormalize quaternion else: try: mapped = eval('map(%s,[N]*len(base),base,new)'%mapping) # map user defined function to colums in chunks except: mapped = ['n/a']*len(base) return mapped # ----------------------------- def OpenPostfile(name,type,nodal = False): """open postfile with extrapolation mode 'translate'""" p = {\ 'spectral': MPIEspectral_result,\ 'marc': post_open,\ }[type](name) p.extrapolation({True:'linear',False:'translate'}[nodal]) p.moveto(1) return p # ----------------------------- def ParseOutputFormat(filename,what,me): """parse .output* files in order to get a list of outputs""" content = [] format = {'outputs':{},'specials':{'brothers':[]}} for prefix in ['']+map(str,range(1,17)): if os.path.exists(prefix+filename+'.output'+what): try: file = open(prefix+filename+'.output'+what) content = file.readlines() file.close() break except: pass if content == []: return format # nothing found... tag = '' tagID = 0 for line in content: if re.match("\s*$",line) or re.match("#",line): # skip blank lines and comments continue m = re.match("\[(.+)\]",line) # look for block indicator if m: # next section tag = m.group(1) tagID += 1 format['specials']['brothers'].append(tag) if tag == me or (me.isdigit() and tagID == int(me)): format['specials']['_id'] = tagID format['outputs'] = [] tag = me else: # data from section if tag == me: (output,length) = line.split() output.lower() if length.isdigit(): length = int(length) if re.match("\((.+)\)",output): # special data, e.g. (Ngrains) format['specials'][output] = length elif length > 0: format['outputs'].append([output,length]) return format # ----------------------------- def ParsePostfile(p,filename, outputFormat): """ parse postfile in order to get position and labels of outputs needs "outputFormat" for mapping of output names to postfile output indices """ stat = { \ 'IndexOfLabel': {}, \ 'Title': p.title(), \ 'Extrapolation': p.extrapolate, \ 'NumberOfIncrements': p.increments(), \ 'NumberOfNodes': p.nodes(), \ 'NumberOfNodalScalars': p.node_scalars(), \ 'LabelOfNodalScalar': [None]*p.node_scalars() , \ 'NumberOfElements': p.elements(), \ 'NumberOfElementalScalars': p.element_scalars(), \ 'LabelOfElementalScalar': [None]*p.element_scalars() , \ 'NumberOfElementalTensors': p.element_tensors(), \ 'LabelOfElementalTensor': [None]*p.element_tensors(), \ } # --- find labels for labelIndex in range(stat['NumberOfNodalScalars']): label = p.node_scalar_label(labelIndex) stat['IndexOfLabel'][label] = labelIndex stat['LabelOfNodalScalar'][labelIndex] = label for labelIndex in range(stat['NumberOfElementalScalars']): label = p.element_scalar_label(labelIndex) stat['IndexOfLabel'][label] = labelIndex stat['LabelOfElementalScalar'][labelIndex] = label for labelIndex in range(stat['NumberOfElementalTensors']): label = p.element_tensor_label(labelIndex) stat['IndexOfLabel'][label] = labelIndex stat['LabelOfElementalTensor'][labelIndex] = label if 'User Defined Variable 1' in stat['IndexOfLabel']: # output format without dedicated names? stat['IndexOfLabel']['HomogenizationCount'] = stat['IndexOfLabel']['User Defined Variable 1'] # adjust first named entry if 'HomogenizationCount' in stat['IndexOfLabel']: # does the result file contain relevant user defined output at all? startIndex = stat['IndexOfLabel']['HomogenizationCount'] stat['LabelOfElementalScalar'][startIndex] = 'HomogenizationCount' # We now have to find a mapping for each output label as defined in the .output* files to the output position in the post file # Since we know where the user defined outputs start ("startIndex"), we can simply assign increasing indices to the labels # given in the .output* file offset = 1 for (name,N) in outputFormat['Homogenization']['outputs']: for i in range(N): label = {False: '%s'%( name), True:'%i_%s'%(i+1,name)}[N > 1] stat['IndexOfLabel'][label] = startIndex + offset stat['LabelOfElementalScalar'][startIndex + offset] = label offset += 1 stat['IndexOfLabel']['GrainCount'] = startIndex + offset stat['LabelOfElementalScalar'][startIndex + offset] = 'GrainCount' # add GrainCount offset += 1 if '(ngrains)' in outputFormat['Homogenization']['specials']: for grain in range(outputFormat['Homogenization']['specials']['(ngrains)']): stat['IndexOfLabel']['%i_CrystalliteCount'%(grain+1)] = startIndex + offset # report crystallite count stat['LabelOfElementalScalar'][startIndex + offset] = '%i_CrystalliteCount'%(grain+1) # add GrainCount offset += 1 for (name,N) in outputFormat['Crystallite']['outputs']: # add crystallite outputs for i in range(N): label = '%i_'%(grain+1) + ('%i_'%(i+1) if N>1 else '') + name stat['IndexOfLabel'][label] = startIndex + offset stat['LabelOfElementalScalar'][startIndex + offset] = label offset += 1 stat['IndexOfLabel']['%i_ConstitutiveCount'%(grain+1)] = startIndex + offset # report constitutive count stat['LabelOfElementalScalar'][startIndex + offset] = '%i_ConstitutiveCount'%(grain+1) # add GrainCount offset += 1 for (name,N) in outputFormat['Constitutive']['outputs']: # add constitutive outputs for i in range(N): label = '%i_'%(grain+1) + ('%i_'%(i+1) if N>1 else '') + name stat['IndexOfLabel'][label] = startIndex + offset try: stat['LabelOfElementalScalar'][startIndex + offset] = label except IndexError: print 'trying to assign %s at position %i+%i'%(label,startIndex,offset) sys.exit(1) offset += 1 return stat # ----------------------------- def SummarizePostfile(stat,where=sys.stdout,format='marc'): where.write('\n\n') where.write('title:\t%s'%stat['Title'] + '\n\n') where.write('extraplation:\t%s'%stat['Extrapolation'] + '\n\n') where.write('increments:\t%i'%(stat['NumberOfIncrements']) + '\n\n') where.write('nodes:\t%i'%stat['NumberOfNodes'] + '\n\n') where.write('elements:\t%i'%stat['NumberOfElements'] + '\n\n') where.write('nodal scalars:\t%i'%stat['NumberOfNodalScalars'] + '\n\n '\ +'\n '.join(stat['LabelOfNodalScalar']) + '\n\n') where.write('elemental scalars:\t%i'%stat['NumberOfElementalScalars'] + '\n\n '\ + '\n '.join(stat['LabelOfElementalScalar']) + '\n\n') where.write('elemental tensors:\t%i'%stat['NumberOfElementalTensors'] + '\n\n '\ + '\n '.join(stat['LabelOfElementalTensor']) + '\n\n') return True # ----------------------------- # MAIN FUNCTION STARTS HERE # ----------------------------- # --- input parsing parser = OptionParser(option_class=damask.extendableOption, usage='%prog options [file[s]]', description = """ Extract data from a .t16 (MSC.Marc) or .spectralOut results file. List of output variables is given by options '--ns','--es','--et','--ho','--cr','--co'. Filters and separations use 'elem','node','ip','grain', and 'x','y','z' as key words. Example: 1) get averaged results in slices perpendicular to x for all negative y coordinates --filter 'y < 0.0' --separation x --map 'avg' 2) global sum of squared data falling into first quadrant arc between R1 and R2 --filter 'x >= 0.0 and y >= 0.0 and x*x + y*y >= R1*R1 and x*x + y*y <= R2*R2' --map 'lambda n,b,a: n*b+a*a' User mappings need to be formulated in an incremental fashion for each new data point, a(dd), and may use the current (incremental) result, b(ase), as well as the number, n(umber), of already processed data points for evaluation. """, version = scriptID) parser.add_option('-i','--info', action='store_true', dest='info', help='list contents of resultfile') parser.add_option('-l','--legacy', action='store_true', dest='legacy', help='data format of spectral solver is in legacy format (no MPI out)') parser.add_option('-n','--nodal', action='store_true', dest='nodal', help='data is extrapolated to nodal value') parser.add_option( '--prefix', dest='prefix', metavar='string', help='prefix to result file name') parser.add_option( '--suffix', dest='suffix', metavar='string', help='suffix to result file name') parser.add_option('-d','--dir', dest='dir', metavar='string', help='name of subdirectory to hold output [%default]') parser.add_option('-s','--split', action='store_true', dest='separateFiles', help='split output per increment') parser.add_option('-r','--range', dest='range', type='int', nargs=3, metavar='int int int', help='range of positions (or increments) to output (start, end, step) [all]') parser.add_option('--increments', action='store_true', dest='getIncrements', help='switch to increment range') parser.add_option('-m','--map', dest='func', metavar='string', help='data reduction mapping [%default] out of min, max, avg, avgabs, sum, sumabs or user-lambda') parser.add_option('-p','--type', dest='filetype', metavar = 'string', help = 'type of result file [auto]') group_material = OptionGroup(parser,'Material identifier') group_material.add_option('--homogenization', dest='homog', help='homogenization identifier (as string or integer [%default])', metavar='string') group_material.add_option('--crystallite', dest='cryst', help='crystallite identifier (as string or integer [%default])', metavar='string') group_material.add_option('--phase', dest='phase', help='phase identifier (as string or integer [%default])', metavar='string') group_special = OptionGroup(parser,'Special outputs') group_special.add_option('-t','--time', action='store_true', dest='time', help='output time of increment [%default]') group_special.add_option('-f','--filter', dest='filter', help='condition(s) to filter results [%default]', metavar='string') group_special.add_option('--separation', action='extend', dest='sep', help='properties to separate results [%default]', metavar='') group_special.add_option('--sort', action='extend', dest='sort', help='properties to sort results [%default]', metavar='') group_general = OptionGroup(parser,'General outputs') group_general.add_option('--ns', action='extend', dest='nodalScalar', help='nodal scalars to extract', metavar='') group_general.add_option('--es', action='extend', dest='elemScalar', help='elemental scalars to extract', metavar='') group_general.add_option('--et', action='extend', dest='elemTensor', help='elemental tensors to extract', metavar='') group_general.add_option('--ho', action='extend', dest='homogenizationResult', help='homogenization results to extract', metavar='') group_general.add_option('--cr', action='extend', dest='crystalliteResult', help='crystallite results to extract', metavar='') group_general.add_option('--co', action='extend', dest='constitutiveResult', help='constitutive results to extract', metavar='') parser.add_option_group(group_material) parser.add_option_group(group_general) parser.add_option_group(group_special) parser.set_defaults(info = False) parser.set_defaults(legacy = False) parser.set_defaults(nodal = False) parser.set_defaults(prefix = '') parser.set_defaults(suffix = '') parser.set_defaults(dir = 'postProc') parser.set_defaults(filetype = None) parser.set_defaults(func = 'avg') parser.set_defaults(homog = '1') parser.set_defaults(cryst = '1') parser.set_defaults(phase = '1') parser.set_defaults(filter = '') parser.set_defaults(sep = []) parser.set_defaults(sort = []) parser.set_defaults(inc = False) parser.set_defaults(time = False) parser.set_defaults(separateFiles = False) parser.set_defaults(getIncrements= False) (options, files) = parser.parse_args() # --- basic sanity checks if files == []: parser.print_help() parser.error('no file specified...') if not os.path.exists(files[0]): parser.print_help() parser.error('invalid file "%s" specified...'%files[0]) # --- figure out filetype if options.filetype is None: ext = os.path.splitext(files[0])[1] for theType in fileExtensions.keys(): if ext in fileExtensions[theType]: options.filetype = theType break if options.filetype is not None: options.filetype = options.filetype.lower() if options.filetype == 'marc': offset_pos = 1 else: offset_pos = 0 # --- more sanity checks if options.filetype not in ['marc','spectral']: parser.print_help() parser.error('file type "%s" not supported...'%options.filetype) if options.filetype == 'marc': sys.path.append(damask.solver.Marc().libraryPath()) try: from py_post import post_open except: print('error: no valid Mentat release found') sys.exit(-1) else: def post_open(): return if options.constitutiveResult and not options.phase: parser.print_help() parser.error('constitutive results require phase...') if options.nodalScalar and ( options.elemScalar or options.elemTensor\ or options.homogenizationResult or options.crystalliteResult or options.constitutiveResult ): parser.print_help() parser.error('not allowed to mix nodal with elemental results...') if not options.nodalScalar: options.nodalScalar = [] if not options.elemScalar: options.elemScalar = [] if not options.elemTensor: options.elemTensor = [] if not options.homogenizationResult: options.homogenizationResult = [] if not options.crystalliteResult: options.crystalliteResult = [] if not options.constitutiveResult: options.constitutiveResult = [] options.sort.reverse() options.sep.reverse() # --- start background messaging bg = damask.util.backgroundMessage() bg.start() # --- parse .output and .t16 files if os.path.splitext(files[0])[1] == '': filename = files[0] extension = fileExtensions[options.filetype] else: filename = os.path.splitext(files[0])[0] extension = os.path.splitext(files[0])[1] outputFormat = {} me = { 'Homogenization': options.homog, 'Crystallite': options.cryst, 'Constitutive': options.phase, } bg.set_message('parsing .output files...') for what in me: outputFormat[what] = ParseOutputFormat(filename, what, me[what]) if '_id' not in outputFormat[what]['specials']: print "\nsection '%s' not found in <%s>"%(me[what], what) print '\n'.join(map(lambda x:' [%s]'%x, outputFormat[what]['specials']['brothers'])) bg.set_message('opening result file...') p = OpenPostfile(filename+extension,options.filetype,options.nodal) bg.set_message('parsing result file...') stat = ParsePostfile(p, filename, outputFormat) if options.filetype == 'marc': stat['NumberOfIncrements'] -= 1 # t16 contains one "virtual" increment (at 0) # --- sanity check for output variables # for mentat variables (nodalScalar,elemScalar,elemTensor) we simply have to check whether the label # is found in the stat[indexOfLabel] dictionary for user defined variables (homogenizationResult, # crystalliteResult,constitutiveResult) we have to check the corresponding outputFormat, since the # namescheme in stat['IndexOfLabel'] is different for opt in ['nodalScalar','elemScalar','elemTensor','homogenizationResult','crystalliteResult','constitutiveResult']: if eval('options.%s'%opt): for label in eval('options.%s'%opt): if (opt in ['nodalScalar','elemScalar','elemTensor'] and label not in stat['IndexOfLabel'] and label not in ['elements',]) \ or (opt in ['homogenizationResult','crystalliteResult','constitutiveResult'] \ and (not outputFormat[opt[:-6].capitalize()]['outputs'] \ or label not in zip(*outputFormat[opt[:-6].capitalize()]['outputs'])[0])): parser.error('%s "%s" unknown...'%(opt,label)) # --- output info if options.info: if options.filetype == 'marc': print '\n\nMentat release %s'%damask.solver.Marc().version('../../') if options.filetype == 'spectral': print '\n\n',p SummarizePostfile(stat) print '\nUser Defined Outputs' for what in me: print '\n ',what,':' for output in outputFormat[what]['outputs']: print ' ',output sys.exit(0) # --- build connectivity maps elementsOfNode = {} for e in xrange(stat['NumberOfElements']): if e%1000 == 0: bg.set_message('connect elem %i...'%e) for n in map(p.node_sequence,p.element(e).items): if n not in elementsOfNode: elementsOfNode[n] = [p.element_id(e)] else: elementsOfNode[n] += [p.element_id(e)] maxCountElementsOfNode = 0 for l in elementsOfNode.values(): maxCountElementsOfNode = max(maxCountElementsOfNode,len(l)) # --------------------------- build group membership -------------------------------- p.moveto(offset_pos) index = {} groups = [] groupCount = 0 memberCount = 0 if options.nodalScalar: for n in xrange(stat['NumberOfNodes']): if n%1000 == 0: bg.set_message('scan node %i...'%n) myNodeID = p.node_id(n) myNodeCoordinates = [p.node(n).x, p.node(n).y, p.node(n).z] myElemID = 0 myIpID = 0 myGrainID = 0 # generate an expression that is only true for the locations specified by options.filter filter = substituteLocation(options.filter, [myElemID,myNodeID,myIpID,myGrainID], myNodeCoordinates) if filter != '' and not eval(filter): # for all filter expressions that are not true:... continue # ... ignore this data point and continue with next # --- group data locations # generate a unique key for a group of separated data based on the separation criterium for the location grp = substituteLocation('#'.join(options.sep), [myElemID,myNodeID,myIpID,myGrainID], myNodeCoordinates) if grp not in index: # create a new group if not yet present index[grp] = groupCount groups.append([[0,0,0,0,0.0,0.0,0.0]]) # initialize with avg location groupCount += 1 groups[index[grp]][0][:4] = mapIncremental('','unique', len(groups[index[grp]])-1, groups[index[grp]][0][:4], [myElemID,myNodeID,myIpID,myGrainID]) # keep only if unique average location groups[index[grp]][0][4:] = mapIncremental('','avg', len(groups[index[grp]])-1, groups[index[grp]][0][4:], myNodeCoordinates) # incrementally update average location groups[index[grp]].append([myElemID,myNodeID,myIpID,myGrainID,0]) # append a new list defining each group member memberCount += 1 else: for e in xrange(stat['NumberOfElements']): if e%1000 == 0: bg.set_message('scan elem %i...'%e) myElemID = p.element_id(e) myIpCoordinates = ipCoords(p.element(e).type, map(lambda node: [node.x, node.y, node.z], map(p.node, map(p.node_sequence, p.element(e).items)))) myIpIDs = ipIDs(p.element(e).type) Nips = len(myIpIDs) myNodeIDs = p.element(e).items[:Nips] for n in range(Nips): myIpID = myIpIDs[n] myNodeID = myNodeIDs[n] for g in range(('GrainCount' in stat['IndexOfLabel']\ and int(p.element_scalar(e, stat['IndexOfLabel']['GrainCount'])[0].value))\ or 1): myGrainID = g + 1 # --- filter valid locations # generates an expression that is only true for the locations specified by options.filter filter = substituteLocation(options.filter, [myElemID,myNodeID,myIpID,myGrainID], myIpCoordinates[n]) if filter != '' and not eval(filter): # for all filter expressions that are not true:... continue # ... ignore this data point and continue with next # --- group data locations # generates a unique key for a group of separated data based on the separation criterium for the location grp = substituteLocation('#'.join(options.sep), [myElemID,myNodeID,myIpID,myGrainID], myIpCoordinates[n]) if grp not in index: # create a new group if not yet present index[grp] = groupCount groups.append([[0,0,0,0,0.0,0.0,0.0]]) # initialize with avg location groupCount += 1 groups[index[grp]][0][:4] = mapIncremental('','unique', len(groups[index[grp]])-1, groups[index[grp]][0][:4], [myElemID,myNodeID,myIpID,myGrainID]) # keep only if unique average location groups[index[grp]][0][4:] = mapIncremental('','avg', len(groups[index[grp]])-1, groups[index[grp]][0][4:], myIpCoordinates[n]) # incrementally update average location groups[index[grp]].append([myElemID,myNodeID,myIpID,myGrainID,n]) # append a new list defining each group member memberCount += 1 # --------------------------- sort groups -------------------------------- where = { 'elem': 0, 'node': 1, 'ip': 2, 'grain': 3, 'x': 4, 'y': 5, 'z': 6, } sortProperties = [] for item in options.sep: if item not in options.sort: sortProperties.append(item) theKeys = [] if 'none' not in map(str.lower, options.sort): for criterium in options.sort + sortProperties: if criterium in where: theKeys.append('x[0][%i]'%where[criterium]) sortKeys = eval('lambda x:(%s)'%(','.join(theKeys))) bg.set_message('sorting groups...') groups.sort(key = sortKeys) # in-place sorting to save mem # --------------------------- create output dir -------------------------------- dirname = os.path.abspath(os.path.join(os.path.dirname(filename),options.dir)) if not os.path.isdir(dirname): os.mkdir(dirname,0755) fileOpen = False assembleHeader = True header = [] standard = ['inc'] + \ (['time'] if options.time else []) + \ ['elem','node','ip','grain','1_pos','2_pos','3_pos'] # --------------------------- loop over positions -------------------------------- bg.set_message('getting map between positions and increments...') incAtPosition = {} positionOfInc = {} for position in range(stat['NumberOfIncrements']): p.moveto(position+offset_pos) incAtPosition[position] = p.increment # remember "real" increment at this position positionOfInc[p.increment] = position # remember position of "real" increment if not options.range: options.getIncrements = False locations = range(stat['NumberOfIncrements']) # process all positions else: options.range = list(options.range) # convert to list if options.getIncrements: locations = [positionOfInc[x] for x in range(options.range[0],options.range[1]+1,options.range[2]) if x in positionOfInc] else: locations = range( max(0,options.range[0]), min(stat['NumberOfIncrements'],options.range[1]+1), options.range[2] ) increments = [incAtPosition[x] for x in locations] # build list of increments to process time_start = time.time() for incCount,position in enumerate(locations): # walk through locations p.moveto(position+offset_pos) # wind to correct position # --------------------------- file management -------------------------------- if options.separateFiles: if fileOpen: file.close() fileOpen = False outFilename = eval('"'+eval("'%%s_inc%%0%ii%%s.txt'%(math.log10(max(increments+[1]))+1)")\ +'"%(dirname + os.sep + options.prefix + os.path.split(filename)[1],increments[incCount],options.suffix)') else: outFilename = '%s.txt'%(dirname + os.sep + options.prefix + os.path.split(filename)[1] + options.suffix) if not fileOpen: file = open(outFilename,'w') fileOpen = True file.write('2\theader\n') file.write(scriptID + '\t' + ' '.join(sys.argv[1:])) headerWritten = False file.flush() # --------------------------- read and map data per group -------------------------------- member = 0 for group in groups: N = 0 # group member counter for (e,n,i,g,n_local) in group[1:]: # loop over group members member += 1 if member%1000 == 0: time_delta = ((len(locations)*memberCount)/float(member+incCount*memberCount)-1.0)*(time.time()-time_start) bg.set_message('(%02i:%02i:%02i) processing point %i of %i from increment %i (position %i)...' %(time_delta//3600,time_delta%3600//60,time_delta%60,member,memberCount,increments[incCount],position)) newby = [] # current member's data if options.nodalScalar: for label in options.nodalScalar: if label == 'elements': length = maxCountElementsOfNode content = elementsOfNode[p.node_sequence(n)]+[0]*(length-len(elementsOfNode[p.node_sequence(n)])) else: length = 1 content = [ p.node_scalar(p.node_sequence(n),stat['IndexOfLabel'][label]) ] if assembleHeader: header += heading('_',[[component,''.join( label.split() )] for component in range(int(length>1),length+int(length>1))]) newby.append({'label':label, 'len':length, 'content':content }) if options.elemScalar: for label in options.elemScalar: if assembleHeader: header += [''.join( label.split() )] newby.append({'label':label, 'len':1, 'content':[ p.element_scalar(p.element_sequence(e),stat['IndexOfLabel'][label])[n_local].value ]}) if options.elemTensor: for label in options.elemTensor: if assembleHeader: header += heading('.',[[''.join( label.split() ),component] for component in ['intensity','t11','t22','t33','t12','t23','t13']]) myTensor = p.element_tensor(p.element_sequence(e),stat['IndexOfLabel'][label])[n_local] newby.append({'label':label, 'len':7, 'content':[ myTensor.intensity, myTensor.t11, myTensor.t22, myTensor.t33, myTensor.t12, myTensor.t23, myTensor.t13, ]}) if options.homogenizationResult or \ options.crystalliteResult or \ options.constitutiveResult: for (label,resultType) in zip(options.homogenizationResult + options.crystalliteResult + options.constitutiveResult, ['Homogenization']*len(options.homogenizationResult) + ['Crystallite']*len(options.crystalliteResult) + ['Constitutive']*len(options.constitutiveResult) ): outputIndex = list(zip(*outputFormat[resultType]['outputs'])[0]).index(label) # find the position of this output in the outputFormat length = int(outputFormat[resultType]['outputs'][outputIndex][1]) thisHead = heading('_',[[component,''.join( label.split() )] for component in range(int(length>1),length+int(length>1))]) if assembleHeader: header += thisHead if resultType != 'Homogenization': thisHead = heading('_',[[g,component,label] for component in range(int(length>1),length+int(length>1))]) try: newby.append({'label':label, 'len':length, 'content':[ p.element_scalar(p.element_sequence(e),stat['IndexOfLabel'][head])[n_local].value for head in thisHead ]}) except KeyError: print '\nDAMASK outputs seem missing from "post" section of the *.dat file!' sys.exit() assembleHeader = False if N == 0: mappedResult = [float(x) for x in xrange(len(header))] # initialize with debug data (should get deleted by *N at N=0) pos = 0 for chunk in newby: mappedResult[pos:pos+chunk['len']] = mapIncremental(chunk['label'],options.func, N,mappedResult[pos:pos+chunk['len']],chunk['content']) pos += chunk['len'] N += 1 # --- write data row to file --- if not headerWritten: file.write('\t'.join(standard + header) + '\n') headerWritten = True file.write('\t'.join(map(str,[p.increment] + \ {True:[p.time],False:[]}[options.time] + \ group[0] + \ mappedResult) ) + '\n') if fileOpen: file.close() # --------------------------- DONE --------------------------------